KR100355955B1 - Apparatus for Generating Microbubbles with Positive Charge by Electrolysis - Google Patents

Abstract

The microbubble generating device having a positive charge by electrolysis according to the present invention comprises: a reaction vessel in which an aqueous solution which is treated raw water is immersed; Cathode metal thin plates which are installed in the reactor and are applied with a voltage from the outside as a negative electrode is applied from the outside to generate hydrogen gas by the electrolysis of the aqueous solution in the reaction tank; And an anode metal sheet which is positively applied from the outside to elute the positive charge of the metal sheet so that the hydrogen gas generated in the cathode metal sheet has a positive charge, wherein the cathode and anode metal sheets are horizontally disposed in the reactor. A negative electrode of an external voltage is applied to a metal thin plate disposed below the metal thin plates, and an anode of an external voltage is applied to a metal thin plate located above the metal thin plates, and a hole is provided in the upper metal thin plate. It is characterized by being drilled. In the microbubble generating device having a positive charge by electrolysis according to the present invention, the hydrogen gas generated by electrolyzing the treatment aqueous solution without the use of a separate air injector is also formed by the cations of the metal eluted by electrolysis. With a positive charge, no separate air injector or surface adsorbent is required. In addition, the negatively charged turbidity-causing substances included in the raw water can be effectively removed by the positively charged microbubbles generated in the microbubble generating device according to the present invention.

Description

Apparatus for Generating Microbubbles with Positive Charge by Electrolysis

The present invention relates to a microbubble generating device used for water treatment, in particular, characterized in that to generate a microbubble having a positive charge by electrolysis.

Conventionally, a water treatment method is known in which fine bubbles are injected to remove particles in water. Dissolved Air Flotation (DAF) generates microbubbles that cause collisions between rising microbubbles and floating or sedimenting particles to lighten the bubbles and aggregates of particles and remove them from the water. It is used to remove low-density particles, such as algae and flocs. Floating beneficiation is used to separate the minerals by blowing air.

According to the collision theory of particles in water, the most important factor in removing particles by injecting microbubbles is the electrostatic property and size of the two factors, of which the electrostatic property is more important. Most of the particles in the water are negatively charged, the fine bubbles injected in the conventional water treatment method also has a negative charge. Therefore, in the related art, since the negatively charged particles must also collide with the negatively charged bubbles, there is a problem that the efficiency is reduced or the pretreatment is excessive.

On the other hand, in the flotation method, the surface adsorbent is used to make fine bubbles with positive charges, thereby increasing the efficiency of water treatment. However, the use of the surface adsorbent in drinking water or natural water not only impairs the safety, but also increases the processing cost. There are disadvantages.

The present invention is to solve the problems of the prior art as described above, and to provide a microbubble generating device having a positive charge, characterized in that the treatment cost is reduced without compromising the safety of the treated water system.

1 is a block diagram of an embodiment of a microbubble generating device according to the present invention,

Figure 2 shows the elution amount of the aluminum cation with time in the microbubble generating device shown in Figure 1,

Figure 3 is a comparison of the turbidity removal rate of the conventional air-injected water treatment method when the microbubble having a positive charge generated by the microbubble generator according to the present invention is applied to the water treatment (electrolysis),

Figure 4 shows the measured amount of aluminum elution according to the voltage applied for electrolysis in the microbubble generating device according to the present invention,

5 is a measurement of turbidity removal rate while changing turbidity of raw water in order to determine whether or not microbubbles having a positive charge generated by the microbubble generating device according to the present invention can be applied to raw water in various states. Showing the results,

Figure 6 is to measure the turbidity removal rate while changing the pH of the raw water in order to find out whether or not the microbubble having a positive charge generated by the microbubble generating apparatus according to the present invention can be applied to the raw water in various states Showing the results,

Figure 7 shows the result of measuring the turbidity removal rate while changing the electrical conductivity of raw water by adding NaCl in order to apply the microbubbles having a positive charge generated by the microbubble generating device according to the present invention in a lake or the sea which,

Figure 8 shows the results of measuring the turbidity removal rate while changing the volume of the reaction solution in order to determine the size of the reactor and the amount of aluminum thin plate used when applying the microbubble generating device according to the present invention,

Figure 9 shows the results of measuring the turbidity removal rate while changing the diameter of the reaction vessel in order to determine the amount of treated water and the appropriate amount of aluminum thin plate in the case of applying the microbubble generating device according to the present invention,

Figure 10 shows the turbidity removal rate for each time period related to the size of the reaction vessel and the hydraulic retention time (HRT) in the microbubble generating device according to the present invention.

In order to achieve the object as described above, the microbubble generating device having a positive charge by the electrolysis according to the present invention, the reaction tank in which an aqueous solution which is raw water to be treated is immersed; Cathode metal thin plates which are installed in the reactor and are applied with a voltage from the outside as a negative electrode is applied from the outside to generate hydrogen gas by the electrolysis of the aqueous solution in the reaction tank; And an anode metal sheet which is positively applied from the outside to elute the positive charge of the metal sheet so that the hydrogen gas generated in the cathode metal sheet has a positive charge, wherein the cathode and anode metal sheets are horizontally disposed in the reactor. A negative electrode of an external voltage is applied to a metal thin plate disposed below the metal thin plates, and an anode of an external voltage is applied to a metal thin plate located above the metal thin plates, and a hole is provided in the upper metal thin plate. It is characterized by being drilled.

In addition, in the microbubble generating device according to the present invention, the metal thin plates may be implemented with aluminum thin plates.

Further, in the microbubble generating device according to the present invention described above, the external voltage applied to the metal thin plates is in the range of 6 to 12V.

Hereinafter, an embodiment of the microbubble generating device according to the present invention will be described in detail with reference to the accompanying drawings.

1 is a block diagram of an embodiment of a microbubble generating device according to the present invention. As shown in FIG. 1, the microbubble generating device according to the present invention includes two sheets of aluminum thin plates 12 and 13 installed horizontally in the reaction vessel 11 in which an aqueous solution, which is treated raw water, is immersed. The spacing of the two aluminum sheets is preferably about 10 mm. The lower aluminum thin plate 12 positioned below is not punched, but the upper aluminum thin plate 13 positioned above is punched 10 mm in diameter 10 mm apart.

When a voltage of 6 to 12 V is applied to the two aluminum thin plates 12 and 13 from the outside, a negative electrode is applied to the lower aluminum thin plate 12, and an anode is applied to the upper aluminum thin plate 13. Hydrogen gas is generated in the lower aluminum thin plate 12, and aluminum is eluted from the upper aluminum thin plate 13.

The reaction in which hydrogen gas is generated in the lower aluminum sheet 12 to which the cathode is applied is represented by the following Chemical Formula 1.

4H ₂ 0 + 4e- → 2H ₂ (g) + 4OH- (aq) E ₀ = -0.83 V

The reaction in which aluminum is eluted from the upper aluminum thin plate 13 to which the anode is applied is represented by Chemical Formula 2 below.

Al (s) → Al ³⁺ (aq) + 3e- E ₀ = +1.66 V

Fine bubbles made of hydrogen gas generated in the lower aluminum thin plate 12 are generated and gradually moved upwards, and then aggregated while passing through the holes of the upper aluminum thin plate 13, by the aluminum cations eluted from the upper aluminum thin plate 13. It will have a positive charge.

In order to measure the rate at which aluminum is eluted from the upper aluminum sheet 13, the voltage of 6V and 11.5V is applied, and the concentration of aluminum in water is measured as time passes, and the result is shown in FIG. Shown in Specifically, samples were taken from a 35 mm high pot from the bottom of the reactor and measured using an Inductively Coupled Plasma Spectrometer (ICP) of the Seoul National University Institute of Technology. As shown in FIG. 2, when the aluminum cation is eluted in the state where the voltage is applied, it can be seen that the dissolution rate and the dissolution amount of Al ³⁺ vary depending on the voltage. It can also be seen that the dissolution rate drops over time.

This aluminum cation causes the hydrogen gas generated from the lower aluminum thin plate 12 to have a positive ion, and the positively charged hydrogen gas is a fine bubble with positive charge, and may be usefully used in a water treatment process in which the particles included are mostly negatively charged. have.

That is, in the microbubble generating device according to the present invention, not only bubbles are injected from the outside, but also microbubbles are generated by electrolysis of an aqueous solution, and the generated microbubbles have a positive charge.

Figure 3 shows the experimental results comparing the turbidity removal efficiency in the water treatment method using a fine bubble generated by electrolysis as in the present invention, and the water treatment method by air injection. Specifically, when no treatment is performed (control group), when only air is injected, in case of electrolysis, when electrolysis and air injection are performed simultaneously, and when air injection is made within 1 minute, when 10 minutes is performed, 20 minutes For each case is shown the initial turbidity and the final turbidity. As shown in FIG. 3, the electrolysis is superior to the turbidity removal effect as compared with the non-electrolysis, and the electrolysis can be seen that the turbidity material is removed well regardless of the air injection. have.

Figure 4 shows the measurement of the amount of aluminum elution according to the voltage applied for the electrolysis in the microbubble generating device according to the present invention, specifically showing two cases of 6V and 11.5V. As shown in Fig. 4, in the case of 6V and 11.5V, although the voltage difference remains nearly twice, it can be seen that the turbidity removal rate is not significantly different. From this, it can be seen that the hydrogen gas does not need a large amount of aluminum cations to have a cation for the aluminum cation. However, when the applied voltage is weak, the generation of hydrogen gas itself may be reduced, which may affect the removal rate, but it may be seen that it does not significantly affect the potential change of hydrogen gas.

5 is a measurement of turbidity removal rate while changing turbidity of raw water in order to find out whether or not microbubbles having a positive charge generated by the microbubble generating device according to the present invention can be applied to raw water in various states. One result is shown. Specifically, raw turbidity was tested for a wide range of changes of 5 NTU (Nephelometric Turbidity Unit), 50 NTU, and 500 NTU. As shown in Figure 5, when the turbidity of the raw water is 50 NTU, 500 NTU shows a nearly 100% removal efficiency. From the above experimental results, it can be seen that it has excellent removal ability in heavy turbidity and high turbidity. On the other hand, at low turbidity of 5 NTU of raw water, the removal efficiency is about 60%, because Al ³⁺ emitted by electrolysis coagulate with each other to cause turbidity. However, this problem can be solved by lowering the electrolysis voltage because the number of particles to be removed is due to excessive release of Al ³⁺ .

Figure 6 is to measure the turbidity removal rate while changing the pH of the raw water in order to find out whether or not the microbubble having a positive charge generated by the microbubble generating apparatus according to the present invention can be applied to the raw water in various states One result is shown. As shown in Fig. 6, it can be seen that the removal efficiency is the highest in the region where the pH of the raw water is intermediate (pH = 7). Therefore, it can be effectively applied in river water, sea water, sewage, etc. to be treated in ordinary water treatment.

Figure 7 shows the result of measuring the turbidity removal rate by changing the electrical conductivity of raw water by adding NaCl in order to apply the microbubbles having a positive charge generated by the microbubble generating device according to the present invention in a lake or the sea It is. As shown in FIG. 7, the removal rate of turbidity does not differ significantly according to the electrical conductivity of raw water.

8 is a result of measuring the turbidity removal rate while changing the volume of the reaction solution in order to determine the size of the reaction vessel and the amount of the aluminum thin plate used in the case of applying the microbubble generating device according to the present invention. As shown in Fig. 8, the larger the volume of the reaction solution, the lower the turbidity removal rate. This is because the size of the aluminum sheet increased only the volume of the reaction solution in a limited state. Therefore, as the volume of the reaction solution increases, the amount of aluminum sheet used must also increase. In case of sudden large fluctuations in the flow rate, the turbidity removal rate may decrease slightly.

9 is a result of measuring the turbidity removal rate while changing the diameter of the reaction vessel in order to determine the amount of treated water and the appropriate amount of aluminum thin plate in the case of applying the microbubble generating device according to the present invention. According to the results shown in FIG. 9, the turbidity removal rate is not significantly affected even by varying the amount of aluminum sheet to treat the same amount of water. In FIG. 9, the turbidity removal rate is almost 100% when the diameter of the reactor is 40 mm and when the diameter is 60 mm.

Figure 10 shows the turbidity removal rate according to time zones related to the size of the reactor and HRT in the microbubble generating device according to the present invention. As shown in Fig. 10, the turbidity removal rate increases with time and then decreases again. This is related to the dissolution rate of Al ³⁺ , and the larger the dissolution rate, the higher the amount of positively charged bubbles, which leads to higher turbidity removal rate.

As described above, in the microbubble generating device having a positive charge by electrolysis according to the present invention, hydrogen gas generated by electrolysis of the treatment aqueous solution is eluted by electrolysis without a separate air injection device. Since positive charges are caused by the cations of the metals, no air injector or surface adsorbent is required. In addition, the negatively charged turbidity-causing substances included in the raw water can be effectively removed by the positively charged microbubbles generated in the microbubble generating device according to the present invention.

Claims (6)

A reaction tank in which an aqueous solution which is treated raw water is immersed; As metal thin plates installed in the reactor and applied a voltage from the outside A cathode metal thin plate to which a cathode is applied from the outside to generate hydrogen gas by electrolysis of an aqueous solution in the reaction tank; And A positive electrode is applied from the outside to the positive charge of the metal sheet is eluted so that the hydrogen gas generated in the above-described negative metal sheet is configured to include a positive metal sheet, The cathode and anode metal thin plates are installed horizontally in the reactor, A negative electrode of an external voltage is applied to a metal thin plate disposed below the metal thin plates, and an anode of an external voltage is applied to a metal thin plate located above the metal thin plates. Microbubble generating device having a positive charge by electrolysis, characterized in that the upper metal plate is a hole. delete delete delete The method of claim 1, The microbubble generating device having a positive charge by electrolysis, characterized in that the metal thin plates are aluminum thin plates. The method according to claim 1 or 5, An apparatus for generating fine bubbles having a positive charge by electrolysis, wherein an external voltage of 6 to 12 V is applied to the aluminum metal thin plates.